Molecular dynamics simulations as a guide for modulating small molecule aggregation

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Azam Nesabi, Jas Kalayan, Sara Al-Rawashdeh, Mohammad A. Ghattas, Richard A. Bryce
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Abstract

Small colloidally aggregating molecules (SCAMs) can be problematic for biological assays in drug discovery campaigns. However, the self-associating properties of SCAMs have potential applications in drug delivery and analytical biochemistry. Consequently, the ability to predict the aggregation propensity of a small organic molecule is of considerable interest. Chemoinformatics-based filters such as ChemAGG and Aggregator Advisor offer rapid assessment but are limited by the assay quality and structural diversity of their training set data. Complementary to these tools, we explore here the ability of molecular dynamics (MD) simulations as a physics-based method capable of predicting the aggregation propensity of diverse chemical structures. For a set of 32 molecules, using simulations of 100 ns in explicit solvent, we find a success rate of 97% (one molecule misclassified) as opposed to 75% by Aggregator Advisor and 72% by ChemAGG. These short timescale MD simulations are representative of longer microsecond trajectories and yield an informative spectrum of aggregation propensities across the set of solutes, capturing the dynamic behaviour of weakly aggregating compounds. Implicit solvent simulations using the generalized Born model were less successful in predicting aggregation propensity. MD simulations were also performed to explore structure-aggregation relationships for selected molecules, identifying chemical modifications that reversed the predicted behaviour of a given aggregator/non-aggregator compound. While lower throughput than rapid cheminformatics-based SCAM filters, MD-based prediction of aggregation has potential to be deployed on the scale of focused subsets of moderate size, and, depending on the target application, provide guidance on removing or optimizing a compound’s aggregation propensity.

Graphical Abstract

Abstract Image

分子动力学模拟作为调节小分子聚集的指南。
小胶体聚集分子(SCAMs)可能会给药物发现活动中的生物检测带来问题。然而,SCAM 的自团聚特性在药物输送和分析生物化学中具有潜在的应用价值。因此,预测小分子有机物聚集倾向的能力相当重要。基于化学信息学的过滤器(如 ChemAGG 和 Aggregator Advisor)可提供快速评估,但受限于其训练集数据的检测质量和结构多样性。作为对这些工具的补充,我们在此探讨了分子动力学(MD)模拟作为一种基于物理的方法预测不同化学结构聚集倾向的能力。对于一组 32 个分子,在显式溶剂中使用 100 毫微秒的模拟,我们发现成功率为 97%(一个分子被误判),而 Aggregator Advisor 的成功率为 75%,ChemAGG 的成功率为 72%。这些短时标的 MD 模拟代表了更长的微秒轨迹,并产生了整个溶质集的聚集倾向信息谱,捕捉到了弱聚集化合物的动态行为。使用广义玻恩模型进行的隐含溶剂模拟在预测聚集倾向方面不太成功。此外,还进行了 MD 模拟,以探索选定分子的结构-聚集关系,确定可逆转特定聚集/非聚集化合物预测行为的化学修饰。虽然与基于快速化学信息学的 SCAM 过滤器相比,基于 MD 的聚集预测吞吐量较低,但有潜力在中等规模的重点子集中进行部署,并根据目标应用,为消除或优化化合物的聚集倾向提供指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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